Collaborative batch aggregation and scheduling in a manufacturing environment

ABSTRACT

In one aspect, a computer-implemented method is provided for aggregating and scheduling product batches in a manufacturing environment. Using a batch aggregation engine implementing a mathematical programming strategy, one or more product demands are allocated to one or more product batches having suggested sizes and suggested starting times. The mathematical programming strategy includes evaluating a number of time-based penalties relative to one another in allocating the demands to the batches, the time-based penalties being based on relationships between suggested starting times for batches and times of demands being considered for allocation to batches. The suggested sizes, the suggested starting times, and feedback relating to the suggested sizes and suggested starting times are communicated from the batch aggregation engine to a scheduling engine to assist the scheduling engine in scheduling starting times for the batches.

RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No. 10/704,080, entitled Collaborative Batch Aggregation and Scheduling in a Manufacturing Environment,” now pending, which is a continuation of U.S. application Ser. No. 10/393,793, entitled “Collaboratively Solving an Optimization Problem Using First and Second Optimization Software Each Having at Least Partial Information Concerning the Optimization Problem,” now U.S. Pat. No. 6,731,998 B1, which is a continuation of U.S. application Ser. No. 09/520,669, entitled “System and Method for Collaborative Batch Aggregation and Scheduling,” now U.S. Pat. No. 6,560,501 B1.

TECHNICAL FIELD OF THE INVENTION

This invention relates generally to the field of aggregating and scheduling batches in a manufacturing environment, and more particularly to collaborative batch aggregation and scheduling in a manufacturing environment.

BACKGROUND

The manufacture of products or other items commonly involves a multi-stage process that includes the use of equipment of various capacities. In such a multi-stage, variable equipment size process, product or end-item demands are often aggregated or split into manufacturing batches in order to fit the available equipment sizes. The scheduling of these batches must account for the complex factory flows between the manufacturing stages and as well as various business rules unique to the particular industry involved. If the manufacturing process is used to produce multiple products, the scheduling process also preferably minimizes sequence-dependent equipment changeovers between the scheduled batches.

Computer implemented planning and scheduling systems are often used for manufacturing and other supply chain planning functions. In general, such systems can model the manufacturing and related environments and provide plans or schedules for producing items to fulfill consumer demand within the constraints of the environment. Existing scheduling systems, however, typically cannot handle variable equipment sizes or make optimal batching decisions using a number of different criteria. Often a manual heuristic scheme is used, based on the personal expertise of a human operator, to divide demand for a product into batches of a single size and to schedule the batches. However, these heuristic schemes often lead to unsatisfactory factory schedules in terms of under-utilized resources, late deliveries, excess inventories, and overall unbalanced factories. Moreover, they necessarily require a person with detailed knowledge of and extensive experience with the manufacturing process for which the batch aggregation and scheduling is required. These and other deficiencies make previous systems and methods for aggregating and scheduling batches inadequate for many purposes.

SUMMARY OF THE INVENTION

According to the present invention, disadvantages and problems associated with previous batch aggregation and scheduling techniques may be reduced or eliminated.

In one aspect, a computer-implemented method is provided for aggregating and scheduling product batches in a manufacturing environment. Using a batch aggregation engine implementing a mathematical programming strategy, one or more product demands are allocated to one or more product batches having suggested sizes and suggested starting times. The mathematical programming strategy includes evaluating a number of time-based penalties relative to one another in allocating the demands to the batches, the time-based penalties being based on relationships between suggested starting times for batches and times of demands being considered for allocation to batches. The suggested sizes, the suggested starting times, and feedback relating to the suggested sizes and suggested starting times are communicated from the batch aggregation engine to a scheduling engine to assist the scheduling engine in scheduling starting times for the batches.

Particular embodiments of the present invention may provide one or more technical advantages. For example, according to decisions and associated feedback communicated between first and second optimization software, the first and second optimization software may collaborate to provide a suitable solution, such as a batch aggregation and scheduling solution where the first optimization software includes batch aggregation software and the second optimization software includes scheduling software. Certain embodiments may allow demands for a product or other item to be aggregated into or split between batches, while also allowing the batches to be scheduled in a manner that increases factory throughput and reduces manufacturing costs. Certain embodiments may be capable of aggregating batches of variable size across multiple production stages and computing material flows between these stages. By allowing for variable batch sizes, certain particular embodiments may enable the use of a variety of equipment sizes in the manufacturing process and optimizes the use of each of these equipment sizes. Certain embodiments may reduce the quantity of work-in-process, minimize end-item inventory, and reduce product shortages and late deliveries. Certain embodiments may be used to optimize other manufacturing and supply chain planning processes, according to particular needs. One or more other technical advantages may be readily apparent to those skilled in the art from the figures, descriptions, and claims included herein.

BRIEF DESCRIPTION OF THE DRAWINGS

To provide a more complete understanding of the present invention and further features and advantages thereof, reference is now made to the following description taken in conjunction with the accompanying drawings, in which:

FIG. 1 illustrates an example system that executes a collaborative batch aggregation and scheduling process to optimize the manufacture of an item;

FIG. 2 illustrates an example collaborative batch aggregation and scheduling process;

FIG. 3 illustrates an example workflow to which a collaborative batch aggregation and scheduling process may be applied;

FIG. 4 illustrates an example allocation of demands to batches using a collaborative batch aggregation and scheduling process;

FIGS. 5A-5D illustrate the relationship between example variables and parameters for use in a collaborative batch aggregation and scheduling process; and

FIG. 6 illustrates an example penalty table for use in a collaborative batch aggregation and scheduling process.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 illustrates an example system 10 that executes a collaborative batch aggregation and scheduling process 12 to optimize the manufacture, packaging, or other handling of a product. The term “product” should be interpreted to encompass any appropriate item or component that might be subject to batch aggregation and scheduling, including any unfinished item or component associated with any stage in a manufacturing, packaging, or other appropriate process. In one embodiment, process 12 involves two engines: a batch aggregation engine 20 and a scheduling engine 30. Batch aggregation engine 20 creates and aggregates product batches according to suitable aggregation criteria described more fully below. All forms of the term “aggregate” should be interpreted to include splitting or dividing a product demand between multiple batches, as well as combining product demands into a batch. In one embodiment, as described more fully below, batch aggregation engine 20 uses mixed-integer linear programming (MILP) to optimize the aggregation of product demands into batches to meet various manufacturing, shipping, customer or other related criteria.

Scheduling engine 30 schedules the aggregated batches according to suitable scheduling criteria. Scheduling engine 30 may include a task-based scheduling system suitable for handling scheduling constraints and minimizing sequence-dependent set-ups, for example only and not by way of limitation, the RHYTHM OPTIMAL SCHEDULER produced by i2 TECHNOLOGIES, INC. and described in U.S. Pat. No. 5,319,781. Batch aggregation engine 20 and scheduling engine 30 cooperate in a collaborative cycle in which the output 22 of aggregation engine 20 serves as input to scheduling engine 30, and the output 32 of scheduling engine 30 serves as input to aggregation engine 20. Such a combination of similarly collaborating engines may be used according to the present invention to optimize the manufacture, packaging, or other handling of any suitable product that is created in batches. Those skilled in the art will appreciate that the present invention may also be used for batch aggregation, scheduling, or both batch aggregation and scheduling in other supply chain planning applications (for example, aggregating and scheduling shipments of products), and that the present invention encompasses all such applications. In addition, batch aggregation engine 20 and scheduling engine 30 may be thought of generically as two optimization engines having partial information about an overall optimization problem. Each engine solves a sub-problem of the overall problem based on its partial information, and the two engines collaboratively pass the solutions to their sub-problems until a sufficiently optimal solution to the overall optimization problem is obtained. Any number of such optimization engines collaboratively working to solve an optimization problem are encompassed by the present invention.

Engines 20 and 30 may operate on one or more computers 14 at one or more locations. Computer 14 may include a suitable input device, such as a keypad, mouse, touch screen, microphone, or other device to input information. An output device may convey information associated with the operation of engines 20 and 30, including digital or analog data, visual information, or audio information. Computer 14 may include fixed or removable storage media, such as magnetic computer disks, CD-ROM, or other suitable media to receive output from and provide input to engines 20 and 30. Computer 14 may include a processor and volatile or non-volatile memory to execute instructions and manipulate information according to the operation of engines 20 and 30. Although only a single computer 14 is shown, engines 20 and 30 may each operate on separate computers 14, or may operate on one or more shared computers 14, without departing from the intended scope of the present invention.

User or automated input 16 may be provided to engines 20 and 30 for use in batch aggregation and scheduling. For example, input 16 may include information about the available capacity and set-up of manufacturing equipment that is entered by a user or automatically supplied by the equipment itself (for example, through the use of sensors). Input 16 may also include one or more demands for a product, the “soft” and “hard” dates by which the demanded product is to be delivered or shipped, and appropriate business rules that affect the manufacturing process (for example, the severity of shipping a particular order late or the cost of storing inventory of a product). As described below, process 12 uses input 16 to aggregate and schedule product batches according to the operation of collaborating engines 20 and 30. The resulting solution, which may include a schedule for making a series of product batches of various sizes using various pieces of equipment, may then be provided to a user, a manufacturing control computer, or any other suitable device related to the manufacturing process as output 18.

FIG. 2 illustrates an example collaborative batch aggregation and scheduling process 12. As described above, batch aggregation engine 20 and scheduling engine 30 cooperate in a collaborative cycle to reach a suitably optimal solution. Within process 12, batch aggregation engine 20 and scheduling engine 30 iteratively attempt to optimize their respective solutions to the overall aggregation and scheduling problem by sharing their respective outputs 22 and 32. Batch aggregation engine 20 communicates output 22 in the form of decisions 24 and feedback 26 relating to decisions 24. Scheduling engine 30 communicates output 32 in the form of decisions 34 and feedback 36 relating to decisions 34. For example, decisions 24 that batch aggregation engine 20 may output may include one or more suggested start times and sizes for each aggregated batch. Decisions 34 output by scheduling engine 30 may include at least one scheduled start time and size for each batch. However, not all decisions 24 made by batch aggregation engine 20 typically need to be or even can be followed by scheduling engine 30. Similarly, not all of the decisions 34 made by scheduling engine 30 typically need to be or even can be followed by batch aggregation engine 20. Each of the engines 20 and 30 is suited to optimize one part of the overall solution, but neither may be able to optimally solve the overall problem by itself. According to the present invention, engines 20 and 30 cooperate to solve the problem and allow appropriate decisions to be made by the best-qualified engine.

For engines 20 and 30 to collaboratively determine a suitably optimal solution, each engine 20 and 30 may pass various penalties as feedback 26 and 36, respectively, relating to its decisions 24 and 34, respectively, that indicate the relative severity of or are otherwise associated with deviating from those decisions. The engine 20 and 30 receiving these penalties weighs the penalties against the information of which it is aware when determining its own decisions 24 and 34, respectively. By iteratively passing decisions and penalties associated with deviating from these decisions, each engine 20 and 30 can thereby influence the decisions of the other engine to collaboratively optimize the manufacturing process.

As an example, assume that there are a series of expected demands 40 for a product over a time horizon 42. Each demand 40 may be associated with an order placed by a customer to be delivered at a particular time in time horizon 42. Batch aggregation engine 20 initially generates a sequence of batches 50 from which to meet demands 40 and determines which demand or demands 40 each batch will be used to meet. In the particular example illustrated in FIG. 2, batch aggregation engine 20 determines that demand 40 a will be met from batch 50 a, which has a suggested size and a suggested start time along time horizon 42. Similarly, batch aggregation engine 20 initially determines that demands 40 b, 40 c and 40 d will all be met from a single batch 50 b, which has a suggested size and a suggested start time that is later in time horizon 42 than the suggested start time for batch 50 a. The sizes of batches 50 a and 50 b may be different, reflecting different sizes of equipment associated with the manufacture of batches 50 a and 50 b.

To make these initial decisions 24, batch aggregation engine 20 typically will have information about product demands 40 and about the equipment available to make product batches 50 to meet demands 40. Batch aggregation engine 20 sends decisions 24 to scheduling engine 30 and, together with or separate from decision 24, also sends feedback 26 in the form of one or more penalties indicating the severity of or otherwise associated with deviating from at least one of the suggested batch sizes or starting times. For example, penalties 26 may include, but are not limited to, a penalty for scheduling a particular batch 50 such that a particular demand 40 is not timely met, a penalty for scheduling a particular batch 50 such that the resulting product will have to be held as inventory before being delivered to the customer or other entity demanding the product, a penalty for using a single batch 50 to meet a demand 40 for two or more packaging sizes, and a penalty for partially utilizing a shipping pallet to meet a demand 40. Other suitable penalties 26 are described in further detail below, although the present invention is intended to encompass all appropriate penalties, whether or not specifically described herein.

After scheduling engine 30 receives the initial decisions 24 and penalties 26 from batch aggregation engine 20, scheduling engine 30 schedules batches 50 c and 50 d of specified sizes (which may or may not be the sizes suggested by batch aggregation engine 20) to begin at specific times 44 along time horizon 42. Scheduling engine 30 determines the actual starting times of batches 50 c and 50 d according to the suggested start times and sizes received from batch aggregation engine 20, the penalties associated with deviating from these suggested sizes and times, and other information scheduling engine 30 may have about the problem, such as the availability of resources, capacity and current set-up state of production equipment, changeover costs associated with changing the current set-up state, labor constraints, material availability, and any other suitable information. Although two batches 50 c and 50 d are illustrated, scheduling engine 30 may schedule more or fewer batches 50 according to particular needs. Scheduling engine 30 schedules the aggregated batches 50, but may have the flexibility not to schedule one or more batches 50. Scheduling engine 30 then sends the actual scheduled starting times of the suggested batch sizes, the actual scheduled starting times and batch sizes of batches not suggested by engine 20, or any combination of these as decisions 34 to batch aggregation engine 20, together with or separate from feedback 36 in the form of one or more appropriate penalties associated with deviating from the scheduled times, sizes, or both times and sizes. In one embodiment, such penalties may discourage the use of over-utilized production resources, may encourage the use of under-utilized resources, may relate to peggings between upstream and downstream batches, or may relate to the compatibility of batches with demands or the compatibility of batches with downstream batches. As an example, penalties 36 may include, but are not limited to, a penalty for deviating from a certain scheduled batch size to encourage the full use of one or more pieces of production equipment over a specified time period or a penalty associated with the changeover time or cost associated with changing the type of product manufactured in a particular piece of manufacturing equipment. Other suitable penalties, whether or not relating to the capacity and operation of the manufacturing equipment or other resources, may be used instead of or in addition to the penalties described above.

The collaborative batch aggregation and scheduling process 12 iterates in a loop until a suitably optimal solution is achieved (for example, when the solutions from each engine 20 and 30 have sufficiently converged or a predetermined number of iterations has been reached). Given the decisions 34 and feedback 36 from scheduling engine 30, batch aggregation engine 20 can re-aggregate demands 40 into batches 50 to achieve a revised solution that is closer to optimal. Batch aggregation engine 20 may output this revised solution as decisions 24 and feedback 26, to be followed by rescheduling and output of a revised solution as decision 34 and feedback 36 from scheduling engine 30. The present invention contemplates some or all of decisions 24 and feedback 26 from batch aggregation engine 20, or decisions 34 and feedback 36 from scheduling engine 30, remaining unchanged from one iteration to the next, as appropriate. The best overall solution to the problem may be stored in memory and provided to a user or a manufacturing-related device (either after meeting a predetermined threshold or after a predetermined number of iterations). In this manner, the iterative process provides for collaborative optimization between possibly very different engines that are applied to solve separate, but related, portions of a larger optimization problem (for example, batch aggregation versus scheduling). Furthermore, although the above example describes a single-stage (product batch to end-item demand) and single-product manufacturing process, process 12 can be advantageously applied to any suitable multi-stage and multi-product manufacturing and shipping problem as described below.

FIG. 3 illustrates an example workflow 100 used in the manufacture, packaging, and shipping of paint, to which the collaborative batch aggregation and scheduling process 12 of the present invention may be applied. Although the example described below involves the manufacture, packaging, and shipping of paint, any other appropriate workflow involving the aggregation of any product, item, or component into batches may also be optimized using the present invention. In the illustrated embodiment, workflow 100 begins with a pre-mix stage 112 that employs a number of pre-mix tanks 110. Pre-mix tanks 110 are used to prepare materials to be used in a subsequent paint mixing stage 122. Mixing stage 122 employs a collection of mixing tanks 120 that each mix materials from the pre-mix stage to form selected colors of paint. The paint colors are typically dependant on the types of pre-mix materials used in mixing stage 122. In workflow 100, there are three mixing tanks 120 a, 120 b, and 120 c which may be used to simultaneously mix different (or the same) colors of paint. After the paint has been mixed, it is routed to fill stage 132 to be placed in containers using one or more fill lines 130. In workflow 100, there are two fill lines: a gallon fill line 130 a and a quart fill line 130 b, although any suitable number of fill lines 130 could be used according to particular needs. Therefore, in this particular example, the various colors of paint mixed in mixing stage 122 can be placed in either one-gallon or one-quart containers. After the paint has been packaged at fill stage 132, the filled paint containers are transported to a palletization stage 140 to be grouped and palletized for shipping to a number of distributors 150 at distribution stage 152.

Workflow 100 therefore presents an example multi-stage (for example, pre-mix, mix, fill, palletization, distribution, or any other suitable combination of stages) and multi-product (for example, various combinations of chemical consistency, color, fill container size, and any other suitable product variables) manufacturing process. Although the end-item demands 40 for workflow 100 are the orders of each distributor 150 for the paint products, each stage in workflow 100 may be considered to place a demand 40 for the “product” from the previous stage. In addition, although not illustrated, workflow 100 may include other suitable stages, such as the supply of raw materials to the pre-mix stage and the supply of paint to retail customers from distributors 150.

Collaborative batch aggregation and scheduling process 12 may be used to compute material flows across these various stages and to assign or “peg” downstream demands 40 (either demands for a finished product or demands for batches of an unfinished product associated with one of these stages) to upstream batches 50 while meeting appropriate business rules and optimization criteria. In one embodiment, batch aggregation engine 20 is used to aggregate demands 40 into batches 50 according to one or more appropriate cost criteria. For example, and not by way of limitation, engine 20 may aggregate batches 50 so as to minimize product shortages and product inventory (“just in time” manufacturing), avoid pallet fragmentation (only one partial pallet per batch 50), meet demand from multiple distributors evenly, or minimize split-fills (using a batch 50 to fill multiple container sizes), singly or in any suitable combination. Output 22 of batch aggregation engine 20, including decisions 24 and feedback 26, is provided to scheduling engine 30, which may tentatively schedule batches 50 so as to minimize sequence-dependent set-up times, minimize costs, maximize throughput, or meet any other suitable objective or objectives. Scheduling engine 30 may provide this suggested schedule to batch aggregation engine 20, as decisions 34 and feedback 36. As described above, batch aggregation engine may use this information to re-optimize the batch aggregation solution. This cycle is continued according to the present invention until an optimal or sufficiently optimal solution is obtained, or until a predetermined number of iterations is reached.

FIG. 4 illustrates an example allocation of demands 40 to batches 50 that might be obtained using batch aggregation engine 20, again using the paint manufacturing process as merely an illustrative example. A table 200 is used to illustrate demands 40 at four time slots 210 for a particular color of paint. Demands 40 are made in this case by two paint distributors 220 a and 220 b, although more or fewer distributors may be involved according to particular needs. To meet demands 40, batch aggregation engine 20 creates three different paint batches 50 a, 50 b, and 50 c. Batches 50 a and 50 b are each manufactured in 150-gallon mixing tanks 202 and 204, respectively. Batch 50 c is manufactured in a 400-gallon mixing tank 206. Batch 50 a totals 145 gallons, such that a small portion of the capacity of tank 202 remains unused. Batches 50 b and 50 c use the entire capacity of their respective tanks 204 and 206, and thus total 150-gallons and 400-gallons, respectively. The example batch aggregation of FIG. 4 has taken palletization into account by minimizing partially-filled pallets (assuming the pallet size of both gallon and quart pallets is twenty units per pallet.)

As illustrated in FIG. 4, batches 50 a and 50 b are each used to meet multiple product demands 40 which arise from multiple distributors 220. These demands 40 are also for multiple container sizes and for different time slots 210. Specifically, batch 50 a is used to meet all 30-gallons of demand 40 a, 15-gallons of demand 40 b, and 100-gallons of demand 40 e. Batch 50 b is used to meet the other 20 gallons of demand 40 b, all 20 quarts (5 gallons) of demand 40 c, all 180-quarts (45 gallons) of demand 40 d, 30-gallons of demand 40 e, and all 50-gallons of demand 40 f. Batch 50 c, on the other hand, is used to meet only one demand 40 from one distributor 220 for one container size. Specifically, batch 50 c is used to meet the remaining 400-gallons of demand 40 e.

As described above, such an allocation or aggregation of demands 40 into batches 50 may be obtained using an MILP model in batch aggregation engine 20. A significant advantage of an MILP approach over manual or other heuristic aggregation techniques is that it allows for a declarative yet flexible formulation of customer-specific aggregation rules and objectives. To use the MILP approach, the problem is preferably broken down into aggregation classes, which in the case of example workflow 100 may each be a particular color of paint for which there is a demand 50 on time horizon 42. Thus, for each color of paint, batch aggregation engine 20 may separately aggregate the product demands 40 (of each of the stages) into batches 50.

In the initial aggregation phase (the first iteration in the cycle of process 12), no batches 50 may yet exist. Therefore, new batches 50 need to be created before assigning demands 40 to batches 50. One complication related to the creation of batches 50 is the fact that workflow 100 may contain tanks of different sizes. Therefore, the batch size generally cannot be specified before a tank is assigned. To optimize batch scheduling, it is preferable that scheduling engine 30 retains the flexibility to assign batches 50 to tanks according to the actual or projected workloads of the tanks. Thus, by deferring to scheduling engine 30 the decision of which batches 50 of a given paint color to schedule, better results may be achieved in terms of throughput since the workload may be balanced across the different equipment sizes. To accomplish this, batch aggregation engine 20 may create a variety of different sizes of batches 50 and prepare a batch penalty table, described more fully below, for each batch 50 to assist scheduling engine 30 in scheduling batch 50. For demands 40 that have been aggregated to batches 50 but for which scheduling engine 30 has decided not to schedule or to schedule late with respect to their associated due dates, re-aggregation by aggregation engine 20 offers the chance to eventually meet all demands 40 timely in the final schedule by re-pegging those demands 40 to the batches 50 that have been scheduled.

In one embodiment, the integrated problem of batch creation, batch sizing, and demand aggregation is approached by creating empty batches 50 that are fixed in time but variable in size (referred to as flex-batches) during a heuristic pre-processing stage. The flex-batches are input to batch aggregation engine 20, which determines the size (possibly zero) of the flex-batches and allocates demands 40 to batches 50 while keeping the starting times of the flex-batches fixed. The freedom that engine 20 has to determine the allocations depends on how many flex-batches are created in the pre-processing stage. In general, the greater number of flex-batches created (for example, creating a flex-batch for every minute on time horizon 42 versus creating a flex-batch for every day on time horizon 42), the more freedom engine 20 has to assign demands 40 to batches 50. However, increased freedom may be associated with an increased processing time, since the determination as to which of the excess batches 50 to leave empty typically enlarges the complexity of the calculations.

Once the flex-batches have been created, batch aggregation engine 20 may use the following example MILP model to optimize the batch aggregation process for workflow 100. In a particular embodiment, the model defines the following indices or sets (which are provided as examples and should not be interpreted as limiting the model) to be used in the calculations as follows: i ∈ P Pre-mix batches j ∈ M Mix batches n ∈ P∪M Overall batches, including pre-mix batches and mix batches k ∈ D Demands, either make to stock or make to order k ∈ D_(f) ⊂ D Demands of fill size f f ∈ F Fill sizes for packing s ∈ S_(n) ⊂ S Possible sizes for batch n (currently S_(n) = S).

The following parameters (which are provided as examples and should not be interpreted as limiting the model) may be used by the model and values for these parameters input to engine 20: Name Description d_(k) Size of demand k ru_(k) Maximum roundup demand allowed with demand k u_(ns) Possible sizes of batch n x_(ns) Lower limit on amount of batch that can be used without “excess” slack penalty l_(ns) Lowest limit on amount of batch used, if batch is of sizes (a physical constraint) Note: l_(ns) ≦ x_(ns) ≦ u_(ns) $u_{n} = {\max\limits_{s}u_{ns}}$ Maximum possible size of batch n $\begin{matrix} {{bsl}_{n}^{\max} = {\max\limits_{s}\left( {u_{ns} - x_{ns}} \right)}} \\ {{besl}_{n}^{\max} = {\max\limits_{s}\left( {x_{ns} - l_{ns}} \right)}} \end{matrix}\quad$ asp Maximum number of split fills allowed per batch t_(k) Due date of demand k t_(n) Time when the batch is scheduled (for inventory and lateness calculations) b_(ij) Material expansion factor for pre-mix i to mix j

The following variables (which are provided as examples and should not be interpreted as limiting the model) may be used in the model's objectives (which are described below): Name Domain Description bs_(n) [0, u_(n)] Batch size available bu_(n) [0, u_(n)] Batch size actually used bsl_(n) [0, bsl_(n) ^(max)] Allowable batch slack besl_(n) [0, besl_(n) ^(max)] Excess slack above maximum bb_(ns) {0, 1} Batch size binary pm_(ij) [0, u_(n)] Amount of pre-mix batch i supplied to mix batch j md_(jk) [0, min(u_(n), d_(k))] Amount of mix batch j supplied to demand k r_(k) [0, ru_(k)] Roundup or phantom demand allowed with demand k (may be 0) mf_(jf) {0, 1} Mix batch j includes SKUs f pack (fill) size f mef_(j) [0, |F| − asp] Number of split fills exceeding asp in mix batch j, where |F| is the size of set F.

FIGS. 5A-5D illustrate several of the above variables and parameters relating to the batch sizes and the amount of batch slack (the amount of unused capacity of a pre-mix or mixing tank). FIG. 5A shows the relationship between these variables when a tank 240 (either a pre-mix or a mixing tank) is filled to a minimum operational level 242. FIG. 5B shows the relationship between these variables when tank 240 is filled to a level 244 above minimum operational level 242, but below a preferable minimum level 246. FIG. 5C shows the relationship between these variables when tank 240 is filled to a level 248 above preferable minimum level 246, but below a maximum operational level 250. FIG. 5D shows the relationship between these variables when tank 240 is filled to maximum operational level 250.

The following weights (which are provided as examples and should not be interpreted as limiting the model) may also be included in the model objectives. The weights are each given a value according to particular needs and are input into batch aggregation engine 20: Name Description wpl Pre-mix earliness wpe Mix earliness wml_(k) Lateness for demand k wme_(k) Earliness for demand k wps Pre-mix slack wpes Pre-mix excess slack wms Mix slack wmes Mix excess slack wf Split fills wef Excess split fills wr_(k) Roundup or phantom demand wpbb_(s) Price for using any pre-mix batch of size s wmbb_(s) Price for using any mix batch of size s Note: wpbb_(s) and wmbb_(s) are used to balance the equipment load across sizes

In one embodiment, after suitable parameters and weights have been input to batch aggregation engine 20, engine 20 aggregates demands 40 into batches 50 such that the sum of the following objectives (which are provided as examples and should not be interpreted as limiting the model) are minimized: $\quad{1.\quad{wpl}{\sum\limits_{i \in P}{\sum\limits_{j \in {M:{t_{i} > t_{j}}}}{\left( {t_{i} - t_{j}} \right) \cdot {pm}_{ij}}}}}$ Lateness of pre-mix batches (delays mix batch processing) $\quad{2.\quad{w{pe}}{\sum\limits_{i \in P}{\sum\limits_{j \in {M:{t_{i} < t_{j}}}}{\left( {t_{j} - t_{i}} \right) \cdot {pm}_{ij}}}}}$ Earliness (work-in-process) of pre-mix batches $\quad{3.\quad{\sum\limits_{k \in D}{{wml}_{k}{\sum\limits_{j \in {M:{t_{j} > t_{k}}}}{\left( {t_{j} - t_{k}} \right) \cdot {md}_{jk}}}}}}$ Lateness of mix batches (penalty will differ for orders and stock) $\quad{4.\quad{\sum\limits_{k \in D}{{wme}_{k}{\sum\limits_{j \in {M:{t_{j} < t_{k}}}}{\left( {t_{k} - t_{j}} \right) \cdot {md}_{jk}}}}}}$ Earliness (end-item inventory) of mix batches $\quad{{5.\quad{wf}{\sum\limits_{j \in M}{\sum\limits_{f \in F}{mf}_{jf}}}} + {{wef}{\sum\limits_{j \in M}{mef}_{j}}}}$ Split fills, plus excess split fills $\quad{6.\quad{\sum\limits_{k \in D}{{wr}_{k}r_{k}}}}$ Roundup/phantom inventory $\quad{{7.\quad{w{ps}}{\sum\limits_{i \in P}{bsl}_{i}}} + {{wpes}{\sum\limits_{i \in P}{besl}_{i}}}}$ Slacks of partially filled pre-mixing tanks $\quad{{8.\quad{wms}{\sum\limits_{j \in M}{bsl}_{j}}} + {{w{mes}}{\sum\limits_{j \in M}{besl}_{j}}}}$ Slacks of partially filled mixing tanks $\quad{9.\quad{\sum\limits_{i \in P}{\sum\limits_{s \in S_{i}}{{wpbb}_{s} \cdot {bb}_{is}}}}}$ Cost for using a pre-mix batch of sizes $10.\quad{\sum\limits_{j \in M}{\sum\limits_{f \in S_{j}}{{wmbb}_{s} \cdot {bb}_{js}}}}$ Cost for using a mix batch of sizes

In one embodiment, batch aggregation engine 20 operates to minimize the sum of one or more of these or other suitable objectives. When determining, in a particular embodiment, the optimal batch aggregation using these objectives, the following constraints (which are provided as examples and should not be interpreted as limiting the model) may be followed: Constraints on All Batches 1.  bs_(n) = bu_(n) + bsl_(n) + besl_(n)  ∀n ∈ P⋃M Size of batch is amount used + slack + excess slack ${2.\quad{bs}_{n}} = {\sum\limits_{s \in S_{n}}{{u_{ns} \cdot {bb}_{ns}}\quad{\forall{n \in {P\bigcup B}}}}}$ Size of each batch depends on the binary selected 3.  l_(ns)bb_(ns) ≤ bu_(n)  ∀n ∈ P⋃B, s ∈ S_(n) Amount of batch used must meet minimum if it is that size 4.  bsl_(n) ≤ (u_(ns) − x_(ns))bb_(ns)  ∀n ∈ P⋃B, s ∈ S_(n) Upper limit on bsl_(n), depending on batch size 5.  besl_(n) ≤ (x_(ns) − l_(ns))bb_(ns)  ∀n ∈ P⋃B, s ∈ S_(n) Upper limit on besl_(n) ${6\quad.\quad{{\sum\limits_{s \in S}}_{n}{bb}_{ns}}}\quad \leq {1\quad{\forall{n \in {P\bigcup B}}}}$ At most one size variable can be selected Constraints on mix batches ${1.\quad{bu}_{j}} = {\sum\limits_{k \in D}{{md}_{jk}\quad{\forall{j \in M}}}}$ Sum of mix batch used must equal total demand supplied ${{2.\quad{bu}_{j}} = {\sum\limits_{i \in P}{b_{ij}{pm}_{ij}}}},\quad{\forall{j \in M}}$ Mix batch used equals scaled amount of pre-mix batch ${{3.\quad{\sum\limits_{k \in D_{f}}{md}_{jk}}} \leq {u_{j}{mf}_{jf}\quad{\forall{j \in M}}}},{f \in F}$ The md_(jk) variable is 1 if there is a fill of that size ${{4.\quad{\sum\limits_{f \in F}{mf}_{jf}}} - {asp}} \leq {{mef}_{j}\quad{\forall{j \in M}}}$ No more than asp fill sizes per batch (split-fills) Constraints on pre-mix batches ${1.\quad{bu}_{i}} = {\sum\limits_{j \in M}{{pm}_{ij}\quad{\forall{i \in P}}}}$ Pre-mix batch used is sum supplied to mix batches ${{2.\quad{\sum\limits_{j \in M}{md}_{jk}}} = {d_{k} + r_{k}}},\quad{\forall{k \in N}}$ Supply total demand for order +roundup (phantom demand that is created)

Using the model described above, in which the sum of the objectives may be minimized according to appropriate constraints, batch aggregation engine 20 is able to aggregate demands 40 for a color of paint (or any other suitable product, item, or component) into batches 50 of different discrete sizes by optimizing material flows across several production stages. The model allows for flexible batch sizes that are desirable for handling different tank fill-levels and minimizing batch slacks. Using the model, batch aggregation engine 20 also helps to reduce the amount of work-in-process, minimize end-item inventory, reduce shortages and lateness of deliveries and reduce split fills. The model described above may be extended, as appropriate, to compute an allocation of pallets to batches 50, minimize partial pallets, and maximize the fairness or equality between supplies to different distributors.

After batch aggregation engine 20 has performed the optimization described above, engine 20 outputs to scheduling engine 30, as decisions 24, the created batches 50 with suggested starting times for each batch 50 that was created. In addition to the suggested batch starting times and sizes, engine 20 outputs feedback 26, in the form of penalties or otherwise, for each batch 50 to be used by scheduling engine 30. Penalties may be communicated to scheduling engine 30 individually or in the form of one or more penalty tables or other groupings.

FIG. 6 illustrates an example penalty table 300 produced by batch aggregation engine 20 that provides information to scheduling engine 30 regarding the effect of deviating from the suggested starting time for a particular batch 50. Penalty table 300 is a mapping of penalty values over time for batch 50. In the illustrated embodiment, penalty table 300 includes penalties indicating the effect on the amount of product shortage and product inventory of moving the starting time of batch 50. However, penalty table 300 may include one or more penalties (instead of or in addition to those described above) associated with any suitable variable or criterion considered by batch aggregation engine 20. Penalty table 300 illustrates that as the batch manufacturing time progresses, the overall inventory penalty decreases. The present invention contemplates penalty table 300 of any suitable shape according to one or more appropriate business rules. For example, if a business rule specifies that no late deliveries are to be made, then as manufacturing time progresses and due dates are missed, the overall slope of the inventory penalty decreases. Conversely, as manufacturing time progresses and “soft” due dates are missed, the shortage penalty slope 320 increases (due to costs associated with missing deadlines). Using penalty table 300 according to the present invention, scheduling engine 30 (which may not otherwise have efficient access to accurate information about shortage and inventory costs) is able to determine the effect that scheduling batch 50 at a particular time has on shortage and inventory costs.

For example, assuming all other criteria considered by batch aggregation engine 20 are equal, engine 20 would typically suggest that batch 50 associated with penalty table 300 be scheduled for a time 330 when the combination of shortage penalty 310 and inventory penalty 320—the composite penalty 340—is minimized. Batch aggregation engine 20 outputs the suggested size and time of batch 50 to scheduling engine 30 along with penalty table 300. Through the use of penalty table 300, scheduling engine 30 is able to acquire knowledge about the shortage and inventory costs associated with scheduling batch 50 at any time during the time range provided in penalty table 300. Using this information, scheduling engine 30 can determine the severity (in terms of the effect on inventory and shortage costs) of deviating from the starting time suggested by batch aggregation engine 20 and can determine whether other factors known to scheduling engine 30 (such as the set-up or capacity of the manufacturing equipment, for example) nevertheless warrant moving the starting time of the batch 50 from the suggested starting time to another starting time. Similar determinations as to batch size may be made according to an appropriate penalty table 300, together with or separate from the determination of the starting time.

As described above, scheduling engine 30 may include a scheduling system such as the RHYTHM OPTIMAL SCHEDULER produced by i2 TECHNOLOGIES, INC. and described in U.S. Pat. No. 5,319,781. Another suitable scheduling engine 30 is described in U.S. Pat. No. 6,456,996, entitled “Computer Implemented Scheduling System and Process Using Abstract Local Search Technique.” Any suitable scheduling engine 30 may be employed without departing from the intended scope of the present invention.

In summary, scheduling engine 30 receives suggested batch sizes and starting times as decisions 24 from batch aggregation engine 20, together with or separate from one or more penalty tables 300 or other suitable feedback 26. If batch aggregation and scheduling for more than one product is being performed, batch aggregation engine 20 may separately calculate and output the suggested batch sizes and batch starting times for each product. The present invention contemplates batch aggregation engine 20 aggregating multiple batches serially, substantially simultaneously, or in any other suitable manner. Based on this input, scheduling engine 30 determines and schedules actual starting times for batches 50 to be used to meet demands 40. If batch aggregation and scheduling is to be performed for more than one product type produced on the same equipment (for example, multiple colors of paint), scheduling engine 30 may concurrently schedule the batches for all products types (so as to properly allocate equipment used in manufacturing all such product types). The present invention contemplates scheduling engine 30 scheduling multiple batches serially, substantially simultaneously, or in any other suitable manner.

The scheduled values for batch starting times (and possibly for batch sizes that were not suggested) are communicated as decisions 34 to batch aggregation engine 20, together with or separately from one or more penalties or other feedback 36 suitable to provide engine 20 with knowledge relating to the information that scheduling engine 30 used to schedule the batches, and to influence batch aggregation engine accordingly. For example only and not by way of limitation, if scheduling engine 30 left a batch 50 suggested by batch aggregation engine 20 unscheduled because that size of manufacturing equipment is fully utilized, then scheduling engine 30 may output a penalty to batch aggregation engine 20 encouraging the creation of batches 50 in sizes that are under-utilized in the schedule. Other penalties based on the criteria considered by scheduling engine 30 may be communicated to batch aggregation engine 20 in addition to or instead of the example penalties described above, and the penalties may be combined in one or more penalty tables 300 for communication to batch aggregation engine 20.

As described above, engines 20 and 30 pass their respective decisions 24 and 34, respectively, and feedback 26 and 36 (in the form of penalties or otherwise), respectively, to each other in an iterative cycle. With each iteration, the batch aggregation and scheduling solution to a particular series of demands over time horizon 42 will typically converge until a solution is obtained that reflects the relative weights of all the criteria considered by engines 20 and 30. Furthermore, to encourage convergence, each engine 20 and 30 may increase with each iteration the penalties associated with deviating from its decisions 24 and 34, respectively, such that after a finite number of iterations a sufficiently optimal solution may become “locked in” and be produced as output 18.

Although the present invention has been described with several embodiments, a plethora of changes, substitutions, variations, alterations, and modifications may be suggested to one skilled in the art, and it is intended that the invention encompass all such changes, substitutions, variations, alterations, and modifications as fall within the spirit and scope of the appended claims. 

1. A computer-implemented method for creating and scheduling batches, comprising: allocating one or more demands to one or more batches having suggested sizes and starting times using a first engine implementing a mathematical programming strategy comprising evaluating a plurality of time-based penalties in allocating the demands to the batches; and communicating the suggested sizes and starting times, and feedback relating to the suggested sizes and starting times, from the first engine to a second engine for use in scheduling starting times for the batches.
 2. The method of claim 1, wherein the mathematical programming strategy comprises a mixed-integer linear programming (MILP) strategy.
 3. The method of claim 1, wherein the feedback communicated from the first engine to the second engine comprises one or more penalties associated with deviating from at least one of the suggested sizes or starting times.
 4. The method of claim 1, further comprising: scheduling starting times for the batches using the second engine according to the suggested sizes and starting times, and related feedback, received from the first engine; and communicating the scheduled starting times and feedback relating to the scheduled starting times from the second engine to the first engine for use in re-allocating one or more demands to one or more batches according to the scheduled starting times and related feedback.
 5. The method of claim 4, wherein the feedback communicated from the second engine to the first engine comprises one or more time-based penalties associated with deviating from at least one of the scheduled starting times.
 6. The method of claim 4, wherein the steps are repeated in an iterative cycle until the first and second engines collaboratively reach a sufficiently optimal solution or until a predetermined number of iterations has been reached.
 7. The method of claim 6, wherein: the feedback communicated from the first engine to the second engine comprises one or more penalties, associated with deviating from at least one of the suggested sizes or starting times, that increase for each iteration in the iterative cycle; and the feedback communicated from the second engine to the first engine comprises one or more penalties, associated with deviating from at least one of the scheduled starting times, that increase for each iteration in the iterative cycle.
 8. A computer-based system for creating and scheduling batches, comprising a first engine operable to: allocate one or more demands to one or more batches having suggested sizes and starting times using a mathematical programming strategy comprising evaluating a plurality of time-based penalties in allocating the demands to the batches; and communicate the suggested batch sizes and starting times, and feedback relating to the suggested sizes and starting times, from the first engine to a second engine for use in scheduling starting times for the batches.
 9. The system of claim 8, wherein the mathematical programming strategy comprises a mixed-integer linear programming (MILP) strategy.
 10. The system of claim 8, wherein the feedback communicated from the first engine to the second engine comprises one or more penalties associated with deviating from at least one of the suggested sizes or starting times.
 11. The system of claim 8, further comprising the second engine coupled to the first engine, the second engine operable to: schedule starting times for the batches according to the suggested sizes and starting times, and related feedback, received from the first engine; and communicate the scheduled starting times and feedback relating to the scheduled starting times to the first engine for use in re-allocating one or more demands to one or more batches according to the scheduled starting times and related feedback.
 12. The system of claim 11, wherein the feedback communicated from the second engine to the first engine comprises one or more time-based penalties associated with deviating from at least one of scheduled starting times.
 13. The system of claim 11, wherein the first and second engines are further operable to communicate their respective outputs to each other in an iterative cycle until they collaboratively reach a sufficiently optimal solution or until a predetermined number of iterations has been reached.
 14. The system of claim 13, wherein: the feedback communicated from the first engine to the second engine comprises one or more penalties, associated with deviating from at least one of the suggested sizes or starting times, that increase for each iteration in the iterative cycle; and the feedback communicated from the second engine to the first engine comprises one or more penalties, associated with deviating from at least one of the scheduled starting times, that increase for each iteration in the iterative cycle.
 15. Computer software for creating and scheduling batches, the software embodied in one or more computer-readable media and when executed operable to: allocate one or more demands to one or more batches having suggested sizes and starting times using first software implementing a mathematical programming strategy comprising evaluating a plurality of time-based penalties in allocating the demands to the batches; and communicate the suggested sizes and starting times, and feedback relating to the suggested sizes and starting times, from the first software to second software for use in scheduling starting times for the batches.
 16. The software of claim 15, wherein the mathematical programming strategy comprises a mixed-integer linear programming (MILP) strategy.
 17. The software of claim 15, wherein the feedback communicated from the first software to the second software comprises one or more penalties associated with deviating from at least one of the suggested sizes or starting times.
 18. The software of claim 15, further comprising the second software, operable when executed to: schedule starting times for the batches according to the suggested sizes and starting times, and related feedback, received from the first software; and communicate the scheduled starting times and feedback relating to the scheduled starting times from the second software to the first software for use in re-allocating one or more demands to one or more batches according to the scheduled starting times and related feedback.
 19. The software of claim 18, wherein the feedback communicated from the second software to the first software comprises one or more time-based penalties associated with deviating from at least one of the scheduled starting times.
 20. The software of claim 18, wherein the steps are repeated in an iterative cycle until the first and second software collaboratively reach a sufficiently optimal solution or until a predetermined number of iterations has been reached.
 21. The software of claim 20, wherein: the feedback communicated from the first software to the second software comprises one or more penalties, associated with deviating from at least one of the suggested sizes or starting times, that increase for each iteration in the iterative cycle; and the feedback communicated from the second software to the first software comprises one or more penalties, associated with deviating from at least one of the scheduled starting times, that increase for each iteration in the iterative cycle. 